dashu_float/root.rs
1use dashu_base::{Approximation, CubicRoot, Sign, SquareRoot, SquareRootRem, UnsignedAbs};
2use dashu_int::{IBig, UBig};
3
4use crate::{
5 error::{assert_limited_precision, panic_root_zeroth, FpError, FpResult},
6 fbig::FBig,
7 repr::{Context, Repr, Word},
8 round::Round,
9 utils::{shl_digits, split_digits_ref},
10};
11
12impl<R: Round, const B: Word> SquareRoot for FBig<R, B> {
13 type Output = Self;
14 #[inline]
15 fn sqrt(&self) -> Self {
16 self.context.unwrap_fp(self.context.sqrt(self.repr()))
17 }
18}
19
20impl<R: Round, const B: Word> CubicRoot for FBig<R, B> {
21 type Output = Self;
22 #[inline]
23 fn cbrt(&self) -> Self {
24 self.context.unwrap_fp(self.context.cbrt(self.repr()))
25 }
26}
27
28impl<R: Round, const B: Word> FBig<R, B> {
29 /// Calculate the square root of the floating point number.
30 ///
31 /// # Panics
32 ///
33 /// Panics if the precision is unlimited.
34 #[inline]
35 pub fn sqrt(&self) -> Self {
36 self.context.unwrap_fp(self.context.sqrt(&self.repr))
37 }
38
39 /// Calculate the nth root of the floating point number.
40 ///
41 /// When `n` is large the computation can be expensive — the significand is
42 /// padded to `n · precision` digits before the integer root is taken, and
43 /// the integer Newton iteration works with numbers of that size. For large
44 /// `n` consider [`powf`][`FBig::powf`] with a rational exponent `1 / n`
45 /// as a faster approximate alternative.
46 ///
47 /// # Examples
48 ///
49 /// ```
50 /// # use core::str::FromStr;
51 /// # use dashu_base::ParseError;
52 /// # use dashu_float::DBig;
53 /// let a = DBig::from_str("16")?;
54 /// assert_eq!(a.nth_root(4), DBig::from_str("2")?);
55 /// # Ok::<(), ParseError>(())
56 /// ```
57 ///
58 /// # Panics
59 ///
60 /// Panics if `n` is zero, or if `n` is even and the number is negative.
61 #[inline]
62 pub fn nth_root(&self, n: usize) -> Self {
63 self.context
64 .unwrap_fp(self.context.nth_root(n, self.repr()))
65 }
66}
67
68impl<R: Round> Context<R> {
69 /// Calculate the square root of the floating point number.
70 ///
71 /// # Examples
72 ///
73 /// ```
74 /// # use core::str::FromStr;
75 /// # use dashu_base::ParseError;
76 /// # use dashu_float::DBig;
77 /// use dashu_base::Approximation::*;
78 /// use dashu_float::{Context, round::{mode::HalfAway, Rounding::*}};
79 ///
80 /// let context = Context::<HalfAway>::new(2);
81 /// let a = DBig::from_str("1.23")?;
82 /// assert_eq!(context.sqrt(&a.repr()), Ok(Inexact(DBig::from_str("1.1")?, NoOp)));
83 /// # Ok::<(), ParseError>(())
84 /// ```
85 ///
86 /// # Panics
87 ///
88 /// Panics if the precision is unlimited.
89 pub fn sqrt<const B: Word>(&self, x: &Repr<B>) -> FpResult<FBig<R, B>> {
90 if x.is_infinite() {
91 return Err(FpError::InfiniteInput);
92 }
93 assert_limited_precision(self.precision);
94 if x.significand.is_zero() {
95 // sqrt(+0) = +0, sqrt(-0) = -0 (preserve the sign of zero)
96 return Ok(Approximation::Exact(FBig::new(x.clone(), *self)));
97 }
98 if x.sign() == Sign::Negative {
99 return Err(FpError::OutOfDomain);
100 }
101
102 // adjust the signifcand so that the exponent is even
103 let digits = x.digits() as isize;
104 let shift = self.precision as isize * 2 - (digits & 1) + (x.exponent & 1) - digits;
105 let (signif, low, low_digits) = if shift > 0 {
106 (shl_digits::<B>(&x.significand, shift as usize), IBig::ZERO, 0)
107 } else {
108 let shift = (-shift) as usize;
109 let (hi, lo) = split_digits_ref::<B>(&x.significand, shift);
110 (hi, lo, shift)
111 };
112
113 let (root, rem) = signif.unsigned_abs().sqrt_rem();
114 let root = Sign::Positive * root;
115 let exp = (x.exponent - shift) / 2;
116
117 let res = if rem.is_zero() {
118 Approximation::Exact(root)
119 } else {
120 let adjust = R::round_low_part(&root, Sign::Positive, || {
121 (Sign::Positive * rem)
122 .cmp(&root)
123 .then_with(|| (low * 4u8).cmp(&Repr::<B>::BASE.pow(low_digits).into()))
124 });
125 Approximation::Inexact(root + adjust, adjust)
126 };
127 Ok(res
128 .map(|signif| Repr::new(signif, exp))
129 .and_then(|v| self.repr_round(v))
130 .map(|v| FBig::new(v, *self)))
131 }
132
133 /// Calculate the cubic root of the floating point number.
134 ///
135 /// # Examples
136 ///
137 /// ```
138 /// # use core::str::FromStr;
139 /// # use dashu_base::ParseError;
140 /// # use dashu_float::DBig;
141 /// use dashu_base::Approximation::*;
142 /// use dashu_float::{Context, round::{mode::HalfAway, Rounding::*}};
143 ///
144 /// let context = Context::<HalfAway>::new(2);
145 /// let a = DBig::from_str("8")?;
146 /// assert_eq!(context.cbrt(&a.repr()), Ok(Exact(DBig::from_str("2")?)));
147 /// # Ok::<(), ParseError>(())
148 /// ```
149 ///
150 /// # Panics
151 ///
152 /// Panics if the precision is unlimited.
153 #[inline]
154 pub fn cbrt<const B: Word>(&self, x: &Repr<B>) -> FpResult<FBig<R, B>> {
155 self.nth_root(3, x)
156 }
157
158 /// Calculate the nth root of the floating point number.
159 ///
160 /// # Examples
161 ///
162 /// ```
163 /// # use core::str::FromStr;
164 /// # use dashu_base::ParseError;
165 /// # use dashu_float::DBig;
166 /// use dashu_base::Approximation::*;
167 /// use dashu_float::{Context, round::{mode::HalfAway, Rounding::*}};
168 ///
169 /// let context = Context::<HalfAway>::new(2);
170 /// let a = DBig::from_str("27")?;
171 /// assert_eq!(context.nth_root(3, &a.repr()), Ok(Exact(DBig::from_str("3")?)));
172 /// # Ok::<(), ParseError>(())
173 /// ```
174 ///
175 /// # Panics
176 ///
177 /// Panics if `n` is zero, if the precision is unlimited, or if `n` is even and `x` is negative.
178 pub fn nth_root<const B: Word>(&self, n: usize, x: &Repr<B>) -> FpResult<FBig<R, B>> {
179 if x.is_infinite() {
180 return Err(FpError::InfiniteInput);
181 }
182 assert_limited_precision(self.precision);
183 if n == 0 {
184 panic_root_zeroth()
185 }
186 debug_assert!(n < isize::MAX as usize);
187 let sign = x.sign();
188 if sign == Sign::Negative && n % 2 == 0 {
189 return Err(FpError::OutOfDomain);
190 }
191 if n == 1 {
192 return Ok(self.repr_round_ref(x).map(|v| FBig::new(v, *self)));
193 }
194 if x.significand.is_zero() {
195 // UBig::ZERO.nth_root(n) erroneously returns ONE, so short-circuit here.
196 // An even root of -0 already errored above, so reaching here the sign is
197 // preserved: odd root of ±0 is ±0.
198 return Ok(Approximation::Exact(FBig::new(x.clone(), *self)));
199 }
200
201 // operate on the magnitude so that shifting/splitting keep a clean sign;
202 // the original sign is re-applied to the result at the end.
203 let xmag: IBig = if sign == Sign::Negative {
204 -&x.significand
205 } else {
206 x.significand.clone()
207 };
208
209 // adjust the significand so that the exponent is divisible by n and the
210 // significand carries at least n*precision digits (required for rounding)
211 let digits = x.digits() as isize;
212 let r = (x.exponent + digits).rem_euclid(n as isize);
213 let shift = n as isize * self.precision as isize - digits + r;
214 let (signif, low, low_digits) = if shift > 0 {
215 (shl_digits::<B>(&xmag, shift as usize), IBig::ZERO, 0)
216 } else {
217 let shift = (-shift) as usize;
218 let (hi, lo) = split_digits_ref::<B>(&xmag, shift);
219 (hi, lo, shift)
220 };
221
222 let mag: UBig = signif.unsigned_abs();
223 let root: UBig = mag.nth_root(n);
224 let rem: UBig = &mag - root.clone().pow(n);
225 let exp = (x.exponent - shift) / n as isize;
226
227 let result_sign = if sign == Sign::Negative {
228 Sign::Negative
229 } else {
230 Sign::Positive
231 };
232 let signed_root: IBig = result_sign * root.clone();
233
234 let res = if rem.is_zero() && low.is_zero() {
235 Approximation::Exact(signed_root)
236 } else {
237 let adjust = R::round_low_part(&signed_root, result_sign, || {
238 // The true value is (mag + low / BASE^low_digits)^(1/n) and
239 // root = floor(mag^(1/n)); its fractional part is compared to 1/2.
240 // frac < 1/2 <=> 2^n * full < (2*root + 1)^n * BASE^low_digits,
241 // where full = mag * BASE^low_digits + low (the full significand).
242 let base_pow = Repr::<B>::BASE.pow(low_digits);
243 let full = &mag * &base_pow + low.unsigned_abs();
244 let lhs = full << n;
245 let rhs = ((root.clone() << 1) + UBig::from_word(1)).pow(n) * base_pow;
246 lhs.cmp(&rhs)
247 });
248 Approximation::Inexact(signed_root.clone() + adjust, adjust)
249 };
250 Ok(res
251 .map(|signif| Repr::new(signif, exp))
252 .and_then(|v| self.repr_round(v))
253 .map(|v| FBig::new(v, *self)))
254 }
255}
256
257impl<R: Round> Context<R> {
258 /// Compute `sqrt(a² + b²)` without spurious overflow/underflow.
259 ///
260 /// This is the overflow-safe scaled sum-of-squares: the larger-magnitude operand is never
261 /// squared. Writing `m = max(|a|, |b|)` and `r = min(|a|,|b|) / m` (so `|r| ≤ 1`), the result is
262 /// `m · sqrt(1 + r²)`, where `1 + r² ∈ [1, 2]` cannot overflow. The final `m · sqrt(1 + r²)`
263 /// overflows only when the true result genuinely exceeds the exponent range (reported as
264 /// [`FpError::Overflow`]). `hypot(±inf, ·) = +inf`, `hypot(0, 0) = +0`.
265 ///
266 /// This is a field-arithmetic-class op (no constant cache), like `sqrt`/`atan2`.
267 ///
268 /// # Panics
269 ///
270 /// Panics if the precision is unlimited.
271 pub fn hypot<const B: Word>(&self, a: &Repr<B>, b: &Repr<B>) -> FpResult<FBig<R, B>> {
272 if a.is_infinite() || b.is_infinite() {
273 return Ok(Approximation::Exact(FBig::new(Repr::infinity(), *self)));
274 }
275 assert_limited_precision(self.precision);
276 if a.significand.is_zero() && b.significand.is_zero() {
277 return Ok(Approximation::Exact(FBig::new(Repr::zero(), *self)));
278 }
279
280 let guard = crate::utils::ceil_usize(<usize as dashu_base::EstimatedLog2>::log2_est(
281 &self.precision,
282 )) + 10;
283 let gctx = Context::<R>::new(self.precision + guard);
284
285 // magnitudes, ordered large >= small (both finite, not both zero here)
286 let a_mag = if a.sign() == Sign::Negative {
287 -a.clone()
288 } else {
289 a.clone()
290 };
291 let b_mag = if b.sign() == Sign::Negative {
292 -b.clone()
293 } else {
294 b.clone()
295 };
296 let (large, small) = if a_mag.cmp(&b_mag).is_ge() {
297 (a_mag, b_mag)
298 } else {
299 (b_mag, a_mag)
300 };
301
302 if small.significand.is_zero() {
303 // hypot(x, 0) = |x|; `large` is already a magnitude
304 return Ok(gctx.repr_round_ref(&large).map(|v| FBig::new(v, *self)));
305 }
306
307 // r = small / large ∈ [0, 1]; 1 + r² ∈ [1, 2] (no overflow); result = large · sqrt(1+r²)
308 let r = gctx.div(&small, &large)?.value();
309 let r2 = gctx.sqr(r.repr())?.value();
310 let sum = gctx.add(&Repr::one(), r2.repr())?.value();
311 let root = gctx.sqrt(sum.repr())?.value();
312 let result = gctx.mul(&large, root.repr())?.value();
313 Ok(result.with_precision(self.precision))
314 }
315}
316
317impl<R: Round, const B: Word> FBig<R, B> {
318 /// Compute `sqrt(self² + other²)` without spurious overflow/underflow.
319 ///
320 /// The result precision is `max(self.precision(), other.precision())`. See
321 /// [`Context::hypot`] for the overflow-safety strategy.
322 ///
323 /// # Examples
324 ///
325 /// ```
326 /// # use core::str::FromStr;
327 /// # use dashu_base::ParseError;
328 /// # use dashu_float::DBig;
329 /// let a = DBig::from_str("3")?;
330 /// let b = DBig::from_str("4")?;
331 /// assert_eq!(a.hypot(&b), DBig::from_str("5")?);
332 /// # Ok::<(), ParseError>(())
333 /// ```
334 ///
335 /// # Panics
336 ///
337 /// Panics if the precision is unlimited.
338 #[inline]
339 pub fn hypot(&self, other: &Self) -> Self {
340 let context = Context::max(self.context, other.context);
341 context.unwrap_fp(context.hypot(&self.repr, &other.repr))
342 }
343}
344
345#[cfg(test)]
346mod tests {
347 use super::*;
348 use crate::round::mode;
349
350 #[test]
351 #[should_panic]
352 fn test_fbig_sqrt_negative_panics() {
353 // sqrt(-1) is out of domain; the FBig layer panics.
354 let neg_one = FBig::<mode::HalfEven>::try_from(-1.0f64).unwrap();
355 let _ = neg_one.sqrt();
356 }
357
358 #[test]
359 fn test_hypot_pythagorean() {
360 let ctx = Context::<mode::HalfEven>::new(53);
361 let mk = |v: i32| Repr::<2>::new(v.into(), 0);
362 // hypot(3, 4) = 5
363 let r = ctx.hypot(&mk(3), &mk(4)).unwrap().value();
364 assert_eq!(r.repr().significand(), &5.into());
365 // hypot(5, 0) = 5
366 let r = ctx.hypot(&mk(5), &mk(0)).unwrap().value();
367 assert_eq!(r.repr().significand(), &5.into());
368 // hypot(0, 0) = 0
369 let r = ctx.hypot(&mk(0), &mk(0)).unwrap().value();
370 assert!(r.repr().is_pos_zero());
371 // hypot(inf, x) = +inf
372 let r = ctx.hypot(&Repr::infinity(), &mk(3)).unwrap().value();
373 assert!(r.repr().is_infinite());
374 assert_eq!(r.repr().sign(), Sign::Positive);
375 }
376
377 #[test]
378 fn test_hypot_no_spurious_overflow() {
379 // a value whose square would collide with the +inf sentinel exponent, but whose
380 // hypot is itself representable: hypot(a, 0) = |a| must not overflow via a².
381 let ctx = Context::<mode::HalfEven>::new(53);
382 // exponent near isize::MAX/2 so that a² would overflow, but |a| is fine
383 let a = Repr::<2>::new(IBig::from(3), isize::MAX / 2);
384 let r = ctx.hypot(&a, &Repr::<2>::zero()).unwrap().value();
385 assert_eq!(r.repr().exponent(), isize::MAX / 2);
386 }
387}